KR20140004175A - Control system for electrochromic device - Google Patents

Abstract

The present invention provides an electronic device that communicates with one of the electrochromic glazing 110 or an insulated glazing unit, an electrochromic glazing or an IGU to a photovoltaic module 100, and an electrochromic glazing and / or photovoltaic module. An electrochromic system comprising module 100 is provided.

Description

CONTROL SYSTEM FOR ELECTROCHROMIC DEVICE}

The invention claims the benefit of the filing date of US Provisional Patent Application No. 61 / 435,391, filed Jan. 24, 2011, entitled "Control System For Electrochromic Device," the disclosure of which is incorporated herein by reference. .

Electrochromic glazings include electrochromic materials known to modify their optical properties, such as coloration, in response to the application of dislocations, thereby rendering such devices somewhat transparent or somewhat reflective. Make. Typical prior art electrochromic devices include a counter electrode layer, an electrochromic material layer deposited substantially in parallel on the counter electrode layer, and an ion conductive layer that separates the counter electrode layer from the electrochromic layer, respectively. In addition, the two transparent conductive layers are substantially parallel to or in contact with the counter electrode layer and the electrochromic layer. Materials for making counter electrode layers, electrochromic material layers, ion conductive layers and conductive layers are known and described, for example, in US 2008/0169185, and are preferably substantially transparent oxides or nitrides. When a potential is applied across the stack structure of the electrochromic device, such as connecting each conductive layer to a low voltage power source, ions such as Li + ions stored in the counter electrode layer are transferred from the counter electrode layer through the ion conductor layer to the electrochromic layer. Flows into. In addition, to maintain charge neutrality in the counter electrode layer and the electrochromic layer, electrons flow from the counter electrode layer to the electrochromic layer, surrounding an external circuit containing a low voltage power source. Movement of ions and electrons into the electrochromic layer results in varying the optical properties of the electrochromic layer, and optionally the counter electrode layer in the complementary EC device, thereby coloring ), And thus the transparency of the electrochromic device.

When installing electrochromic glazings, installing wires for power and control through the building's window framing system and the building's structural systems / supports It can be difficult and costly. A well-designed radio controller combined with photovoltaic cells can dramatically reduce the cost and complexity of installation, and can reduce the cost and complexity, especially for architectural retrofit applications. The combination of photovoltaic cells and electrochromic provides good synergy, generally with tinting only needed in daylight, and with greater solar energy indicates greater tinting. Designing such a product for ease of manufacture and installation presents many challenges when considering the variety of framing systems and the stringent aesthetic requirements of the building. To complicate the situation, the electronics must be replaceable without replacing or deglazing the unit, and if the battery is used it also needs to be user replaceable.

One aspect of the invention is an electrochromic glazing (“EC glazing”) having a light transmittance that is variable in response to a current; At least one photovoltaic module for providing a current in response to light from a light source incident on the photovoltaic module; And a photovoltaic module and an electronic module in communication with the electrochromic glazing. The device for modulating transmission of light from a light source. In some embodiments, the electronic module is in wireless communication with a building automation system. In other embodiments, the photovoltaic module is mounted adjacent to the electrochromic glazing on the exterior building framework. In still other embodiments, the photovoltaic module and / or electronic module is integrated in an electrochromic glazing assembly. In still other embodiments, the photovoltaic module (“PV module”) is combined with an electronic module. In still other embodiments, such a system also includes a battery.

Another aspect of the invention is an electrochromic glazing having a light transmittance that is changeable in response to a current; At least one photovoltaic module electrically connected to the electrochromic glazing to provide a current to the electrochromic glazing in response to light from a light source incident on the photovoltaic module; And an electronic module in communication with either the photovoltaic module or the electrochromic glazing. In another embodiment, the electronic module is in wireless communication with a building automation system. In another embodiment, the photovoltaic module is mounted adjacent to an electrochromic glazing on an interior or exterior building framework. In another embodiment, the photovoltaic module is mounted on the inner or outer surface of the electrochromic glazing or in an insulated glazing unit. In some embodiments, the photovoltaic module includes a photovoltaic material, which can be an inner or outer layer in a glass laminate. In another embodiment, the electrochromic glazing is a laminate of at least two glass panes and the photovoltaic module is mounted between the laminated glass panes. In another embodiment, the electronic module is mounted on the inner or outer surface of the electrochromic glazing or in an insulated glazing unit. In another embodiment, the electronic module is mounted adjacent to the electrochromic glazing on the interior or exterior building framework.

In another embodiment, the photovoltaic module and the electronic module are mounted at different locations. In another embodiment, a photovoltaic module is located on an exterior surface, the electronic module is located inside the framing system, or protrudes into the framing system, and the electronic module is in wireless communication with the building automation system. In another embodiment, a photovoltaic module is located on an outer surface, and the electronic module is located in an inner framework, where the electronic module is in wireless communication with the building automation system. In another embodiment, the electronic module also includes a battery. In another embodiment, the photovoltaic module is located on an internal insulating glazing surface, the electronic module is located in an internal framework, the electronic module is in wireless communication with the building automation system, and the electronic module also includes a battery. In another embodiment, the photovoltaic module is located in an electrochromic glass laminate.

In another embodiment, the photovoltaic module and the electronic module are combined into a single unit. In another embodiment, the combined photovoltaic and electronic modules have a thickness of less than about 10 mm.

In another embodiment, the electronic module responds to solar intensity such that the electrochromic glazing is tinted or colored in proportion to the available sunlight. In another embodiment, the electronic module includes control logic means. In another embodiment, the control logic means monitors the energy available from the photovoltaic module.

In another embodiment, the device also includes a battery. In another embodiment, the electrochromic glazing or IGU comprises a privacy or anti-glare coating. In some embodiments, the IGU comprises two EC glazings.

In another embodiment, the photovoltaic module and the electronic module are combined and mounted adjacent to the electrochromic glazing on the building framework. In another embodiment, the electronic module is in wireless communication with the building automation system.

In another embodiment, the electronic module includes a photovoltaic module and a resistor wired in parallel with the electrochromic glazing wiring.

In another embodiment, the photovoltaic module is connected to the electronic module via electrical feed-through. In another embodiment, the photovoltaic module is coupled to the electronic module via wireless energy transfer means.

Another aspect of the invention is an electrochromic glazing having a light transmittance that is changeable in response to a current; At least one photovoltaic module electrically connected to the electrochromic glazing to provide a current to the electrochromic glazing in response to light from a light source incident on the photovoltaic module; And an electronic module in communication with either the photovoltaic module or the electrochromic glazing, the electronic module being a device for modulating transmission of light from a light source in wireless communication with a building automation system or other interface / control system.

In another embodiment, the photovoltaic module is mounted adjacent to the electrochromic glazing on an interior or exterior building framework. In another embodiment, the photovoltaic module is mounted on the inner or outer surface of the electrochromic glazing or in an insulated glazing unit. In another embodiment, the electrochromic glazing is a laminate of at least two glass panes, and the photovoltaic module is mounted between the laminated glass panes. In another embodiment the electronic module is mounted on the inner or outer surface of the electrochromic glazing or in an insulated glazing unit. In another embodiment, the electronic module is mounted adjacent to the electrochromic glazing on the interior or exterior building framework.

In another embodiment, the photovoltaic module and electronic module are mounted at different locations. In another embodiment, the photovoltaic module is located on an exterior surface, the electronic module is located within or protrudes into the framing system, and the electronic module is in wireless communication with the building automation system. In another embodiment, the photovoltaic module is located on an outer surface, the electronic module is located in an inner framework, and the electronic module is in wireless communication with the building automation system. In another embodiment, the electronic module further comprises a battery. In another embodiment, the photovoltaic module is located on an insulated glazing surface therein, the electronic module is located within the internal framework, the electronic module is in wireless communication with the building automation system, and the electronic module also includes a battery. In another embodiment, the photovoltaic module is located in an electrochromic glass laminate.

In another embodiment, the photovoltaic module and the electronic module are combined into a single unit. In another embodiment, the combined photovoltaic and electronic modules have a thickness of less than about 10 mm.

In another embodiment, the electronic module responds to solar intensity such that the electrochromic glazing is tinted or colored in proportion to the available sunlight. In another embodiment, the electronic modules comprise control logic means. In another embodiment, the control logic means monitor the available energy from the photovoltaic module.

In another embodiment, such device further comprises a battery.

In another embodiment, the photovoltaic module and the electronic module are combined and mounted adjacent to the electrochromic glazing on the building framework. In another embodiment, the electronic module is in wireless communication with the building automation system.

In another embodiment, the electronic module includes a resistor and a photovoltaic module wired in parallel with the electrochromic glazing wiring.

In another embodiment, the photovoltaic module is connected to the electronic module via an electrical feedthrough. In another embodiment, the photovoltaic module is coupled to the electronic module via wireless energy transfer means.

Another aspect of the invention is an electrochromic glazing having a light transmittance that is changeable in response to a current; At least one photovoltaic module electrically connected to the electrochromic glazing to provide a current to the electrochromic glazing in response to light from a light source incident on the photovoltaic module; And an electronic module in communication with either the photovoltaic module or the electrochromic glazing, wherein the electronic module is a method for manufacturing a device for modulating transmission of light from a light source in selective wireless communication with a building automation system.

1 shows an electronic module comprising a resistor and a photovoltaic module wired in parallel with the electrochromic glazing.
2 illustrates communication between a photovoltaic module, an electronic module, and an electrochromic glazing.
3 provides a flowchart illustrating operational control and logic of an embodiment of an electronic module.
4 illustrates the integration between the photovoltaic module, the electronic module, and the electrochromic device.
5A-5D provide configurations of a control system having a photovoltaic module, an electronic module, and an electrochromic glazing.
6 provides a configuration of a control system having a photovoltaic module, an electronic module, and an electrochromic glazing.
7A-7E provide configurations of a control system having a photovoltaic module, an electronic module, and an electrochromic glazing.
8A-8F provide configurations of a control system having a photovoltaic module, an electronic module, and an electrochromic glazing.
9A-9B provide configurations of a control system having a photovoltaic module, an electronic module, and an electrochromic glazing.

The present invention relates to electrochromic glazing or insulated glazing units (hereinafter "IGU"), electrochromic glazings or photovoltaic cells ("PV") modules for powering IGUs, and electrochromic glazing units and / or Or an electrochromic system comprising an electronic module in communication with one of the photovoltaic modules.

Insulated glazing units, as used herein, are separated by spacers along the edges and sealed to create dead air (or other gas such as argon, nitrogen, krypton) spaces between the layers. seal, means two or more glass layers. The terms "electrochromic glazing" or "IGU" are used interchangeably herein. Electrochromic glazing may have a laminate structure (see co-pending US patent applications Ser. Nos. 13 / 040,787 and 13 / 178,065. The disclosures of those applications are incorporated herein by reference in their entirety).

Electrochromic glazing and / or IGU are typically used for architectural purposes such as architectural windows in buildings. Thus, electrochromic glazings or IGUs may be used as window panes or other types of building frameworks (collectively "frame-work" or "building frame-work" herein). Is referred to as). As one of ordinary skill in the art will appreciate, building frameworks often include a frame cap on the outside of the frame. The frame cap is generally an aesthetic extrusion that can be mounted onto the frame near the end of the assembly process and later removed. This technique may be adapted for use in other applications, such as in the transportation industry, for example, in vehicles.

The photovoltaic module (s) may be placed in any position that may be appropriately seen by one of ordinary skill in the art. In some embodiments, photovoltaic modules are located externally on or around a building framework. In other embodiments, photovoltaic modules are disposed directly on the electrochromic glazing or IGU surface, typically at the bottom, when the glass is vertical to minimize shading. If the electrochromic glazing is a laminate structure, the photovoltaic module (s) can be laminated between glass panes, which is a common construction method for photovoltaic panels. One of ordinary skill in the art may include as many photovoltaic cells in a photovoltaic module as necessary to properly power the electrochromic glazing and / or the electronic module. Typically, assuming cell efficiencies of about 15% to about 20%, they will comprise between about 2% and about 8% of the glass area. The most common configuration for such photovoltaic modules is glass laminate. Alternative modules, such as those manufactured by SunWize of San Jose, California, are constructed by mounting solar cells on a fiberglass substrate and encapsulating with polyurethane, which results in a thin, light but robust module.

The photovoltaic module and optional battery will be sized according to the application and environmental details. For example, the 15-foot south-facing 15-foot ² IGU (Golden, CO.) Southward, which is expected to respond automatically only to daylight, is a 3W (peak) solar panel and an 8 Wh Li-ion battery. May require only, but on the other hand, the trend in Bosie ID, which is expected to be manually tinted for daytime 10% glare, the 15 square foot IGU is 4.5W solar panel and 12 Wh Requires a battery.

Additional features of photovoltaic modules, their combined use with electrochromic glazings or IGUs, and choices for their positioning relative to electrochromic glazing or IGUs, the disclosure of which is hereby incorporated by reference in its entirety. Described in US Pat. No. 6,055,089.

In some embodiments, the photovoltaic module and electronic modules are combined in whole or in part in a single package or module. For example, the electronic module can be coupled behind the cells in the PV module. This combined module can be located on the building framework, inside or outside surfaces of the electrochromic glazing, or even within the electrochromic IGU.

When separated from the photovoltaic module, the electronic module may be located in the interior or exterior portions of any building framework as described further herein. In other embodiments, the electronic module may be located on the back side of the IGU itself.

One of ordinary skill in the art would be able to design suitable electronic modules that combine those features typically associated with solar power electronics and electrochromic devices. Conventional components known to those of ordinary skill in the art include (i) embedded 8-bit or 16-bit microcontrollers, typically those made by MicroChip or Cypress Semiconductor. Microprocessor control using; (ii) linear or switching voltage regulators providing a variable voltage for the electrochromic glazing; (iii) wireless communication modules, (iv) linear or switching voltage regulators that convert photovoltaic voltage into circuit requirements; (v) battery charge / discharge control components; And (vi) batteries or super capacitors that allow for faster switching at low light. Any of these features may be used alone or in combination to create a suitable electronic module. In some embodiments, the microprocessor manages all the functions of voltage conversion, battery control, and communications (wired or wireless). In some embodiments, the wireless module includes transceiver circuitry and an antenna (for RF communication). In other embodiments, the electronic module can be combined with other optional components such as a battery.

In some embodiments, the electronic module responds to solar intensity and causes the electrochromic glazing or IGU to tint or color in proportion to the available sunlight. In some embodiments, the electronic module includes a resistive and photovoltaic module wired in parallel with the electrochromic glazing wiring as shown in FIG. 1.

As an example, Table 1 illustrates a sample performance calculation using two crystalline photovoltaic cells to provide for a maximum of about 1.1V, a peak current of 1A, and a resistive load of about 2 Ohms. The resistor will need to be rated for at least 1 W and may be of any suitable type, such as wirewound or carbon composition. In Table 1, the PV + resistance voltage is derived from the typical response curves of crystalline PV cells. The EC tint level is derived from the PV + resistance voltage, using measurements of the tint level as a function of the voltage at equilibrium. The solar output is simply the product of the available sunlight and the EC tint level, and the internal light is simply the product of the solar output and a typical full-sun illuminance value of 100 klux. This table shows how the resistor can function to maintain a constant internal illuminance. It is believed that such a manual system results in a very low total cost with simple installation.

 Sunlight available (percent of full solar energy incident on the IGU)  PV + Resistance Output (V)  EC Tint Level (%)  Solar output (percent of complete solar energy passing EC) Internal light (klux)
(Illuminance passing through EC)  100%  1.1  10%  10.00%  10  80%  1.08  11%  8.80%  8.8  60%  1.05  12%  7.20%  7.2  40%  0.8  25%  10.00%  10  20%  0.4  50%  10.00%  10  0%  0  60%  0.00%  0

In other embodiments, the electronic module includes control logic that applies opposite polarity at low light levels to ensure a fully clear state and an optimized response to daylight. Communication between the photovoltaic module, electronic module, and electrochromic glazing is shown in FIG. 2.

A flow chart illustrating the operation control or logic of an embodiment of an electronic module is shown in FIG. 3.

In some embodiments, an electronic module alone or in combination with a photovoltaic module may wirelessly communicate with a central control system, building management system (BMS), or other user interface (collectively referred to herein as a “control system”). Can be. For example, the BMS interface can be a BACnet, LonWorks, KNX, or any other such interface. In these embodiments, wireless communication may be rapid, for example, in manual over-ride selection of a particular state, synchronization between multiple panes, or integration with building automation systems, and optionally at low light. It can be used for energy storage (batteries or super capacitors) that allow switching or switching to anticipate events (such as sunrise or sunset).

The control system is described above via infrared pulses, radio waves, ultrasound waves, or other wireless communication media described in US Pat. Nos. 7,277,215, 7,133,181, and 6,055,089, which are hereby incorporated by reference in their entirety. You can connect to chromic systems. Other features of a control system that can be integrated into the present invention are also described in the patents above. In some embodiments, wireless communications are over a standard protocol, such as a Zigbee mesh protocol, 802.11 WiFi, or Bluetooth. Proprietary solutions may also be used. Wireless communication protocols will typically be achieved using integrated circuits or modules designed specifically for that purpose. Suitable modules for that purpose include, for example, those manufactured by Digi International, Synapse Wireless, Motorola, or Panasonic.

In some embodiments, when the electronics are inside the building, there will be a surface available for mounting the antenna, which antenna may be a separately mounted module, a component within the electronic module, or a printed wiring board. : PWB) can be designed by itself. In other embodiments, the antenna may be formed on the glass itself from transparent conductors or bus bar material. In still other embodiments, the photovoltaic module can have space to mount a flat antenna structure, such as where no photovoltaic cells are present.

Communication and / or integration between photovoltaic modules, electronic modules, and electrochromic devices in wireless communication with a link to a user interface or automation system is shown in FIG. 4.

The electronic module may also be in direct communication with other electronic modules in other building systems or other electrochromic systems (via wireless or wired communication) in some embodiments. For example, when a Zigbee mesh is used, all units can talk directly to each other, allowing to coordinate the tint level for a uniform appearance. A module with a Bluetooth interface can communicate directly with wireless telephones. A module with a WiFi (802.11) interface can communicate directly with desktop or portable PCs or routers.

In some embodiments, the electrochromic systems also include a battery separate from the electronic module. In other embodiments, the battery is rechargeable or user replaceable, i.e., routine maintenance, and the battery (or batteries) may be replaced if its performance is poor. Suitable batteries include those based on various lithium technologies, nickel-cadmium, or nickel-metal-hydride. Lithium-ion cells with iron phosphate cathodes (LiFePO4 cells) provide long life, good performance over temperature, and adequate safety for this application. When alternative storage technologies are involved, they may be suitable for use in the present invention, including technologies such as supercapacitors / ultracapacitors or thin film batteries.

The photovoltaic module or electronic module may optionally include additional interfaces or modules for future expansion purposes. Any control system can likewise be used to control these additional interfaces or modules. For example, it is entirely possible to integrate interfaces or modules for future addition of light emitting systems, such as for example LED lights, into an information display indicating the status or other information of each electrochromic system or glazings. Specific examples of the electrochromic glazing / IGU, photovoltaic module, and different methods of integrating the electronic module into the electrochromic system are further described in the following examples.

 In a first aspect of the invention (see FIG. 5), a combined photovoltaic / electronic module 100 (with or without wireless communication) for the electrochromic glazing 110 is provided in a building or window framing system ( 130 is mounted on the outside. In some embodiments, a photovoltaic / electronic module (with wireless communication) is a frame having available space in the frame for external access and electrical connection 120 to the glazing pocket, as shown in FIG. 5. Mounted on the part of the. A glazing pocket (that term is understood in the art) is an unfilled space directly surrounding the IGU allowing for IGU size tolerance and installation. Pressure-place systems are an example of such a system. In some embodiments, the electrical connection 120 between the IGU and the control systems consists of a water resistant electrical connector that can supply the voltage and current requirements of the IGU. Other elements of FIG. 5 include outer seal 140, clamp plate cover 150, frame clamp plate 160, inner seal 170, and inner frame 180.

The combined photovoltaic / electronic module (with wireless communication) may have any thickness. In some embodiments, to minimize its visual impact, the combined PV / wireless control module is preferably less than about 10 mm thick, more preferably less than about 6 mm thick. In some embodiments, the visible surface will consist almost entirely of photovoltaic surface (cells). PV and / or electronic modules attached to the pressure plate allow for installation after the glass is installed and then easy replacement in case of failure or damage. Having a PV module on the pressure plate allows a suitable area for solar energy capture without affecting the vision area of the glazing and maximizes the opportunity for daylight.

In a second aspect of the invention (see FIG. 6), a photovoltaic module 200 is mounted on an interior surface 230, and the electronic module 205 is in or protrudes into a building or window framing system. It is believed that this will further minimize the resulting system profile. In some embodiments, the electronic device can hang freely. In still other embodiments, the electronics can be mounted to the pressure plate, as shown in FIG. 6. Other features include outer seal 240, clamp plate cover 250, frame clamp plate 260, outer surface 230, electrochromic device or IGU 210, inner seal 270, and outer frame 280. ).

In a third aspect of the invention (see FIG. 7), the electronic module 305 is moved to an inner frame when compared to the arrangement shown in FIG. 6. It is believed to have the advantage of allowing replacement of the electronic module or replacement of a rechargeable rechargeable battery from the interior of the space. In this illustrated embodiment (and others that follow), the electronic module and battery can be combined or kept separate in a single unit.

In a fourth aspect of the invention, the photovoltaic module 405 is located within IGU 475 as shown in FIG. 8. In some embodiments, electronic module 465 is located within an interior building frame. It is believed that this can result in partial loss of visual area, and this design is believed to simplify installation by eliminating wiring connections. It is believed that this particular embodiment reduces cost and improves reliability by eliminating the need to seal the perimeter of the photovoltaic unit. Based on about 15% -20% efficiency crystalline cells comprising a photovoltaic module, about 2% to about 3% of the glass area is required for systems with batteries or 8% for systems without batteries. Is estimated to be due to the demand for high current when switching rapidly at the appropriate light levels. Other components shown include IGU glazing lite 415, electrochromic layers 425, IGU interior cavity 435, and IGU spacers and seals 455.

In some embodiments, when the photovoltaic module is behind an electrochromic surface (eg, see FIG. 8B), the switching films may need to be removed or at least deactivated to ensure maximum energy availability. In some embodiments, the photovoltaic module is mounted inside the IGU and (1) is mounted on top of the non-switching electrochromic layer region; (2) Laminated in the EC film layers.

In this configuration, the same bus bar system used by the electrochromic glass can be used to bring power to the external circuit. In addition, the photovoltaic module can, in some embodiments, share a common connection with the electrochromic glass. For example, a two-busbar electrochromic IGU with photovoltaic cells may only require three electrical penetrations. Further information on relevant positioning is described in US Pat. No. 6,055,089, which is incorporated herein by reference in its entirety.

In another embodiment where the electrochromic glass is laminated to another piece of glass so that the electrochromic films face away from the lamination surface, the photovoltaic cells may be laminated between the panes. In other embodiments, the photovoltaic module is a photovoltaic film laminated between two slazing or glass lites, preferably on the outer side of the electrochromic film layers (see eg FIG. 8D). Layers may be included. This uses standard PV-laminate manufacturing techniques, and in some embodiments will have a separate set of wiring fee-throughs from the electrochromic glass. In this configuration, it is believed that more energy will be available because sunlight will only pass through a single glass pane to reach the photovoltaic module. In some embodiments, the laminate can be part of a triple pane IGU. For example, FIG. 8F illustrates photovoltaic film layers laminated within a triple pane IGU, where the triple pane IGU is an exterior glazing lite pane 416, an internal glazing light pane 417, and Inner glazing light pane 418 is included. The configuration of FIG. 8F is also a privacy technology film layer 495 (eg, which may be laminated on the innermost face of the inner glazing light of the IGU or on the innermost glazing light). And / or optionally one or both of the second electrochromic film layer 490 (which may be laminated on the innermost face of the inner glazing light of the IGU, or on the innermost glazing light). have.

In still other embodiments, the photovoltaic module may be mounted inside the IGU cavity, preferably on the outer side of the electrochromic film layers (eg, FIG. 8E).

In a fifth aspect of the invention (see FIG. 9), such a configuration holds the photovoltaic module 405 inside the IGU but moves the electronic module 465 to the back of the IGU. This is believed to have the advantage of being virtually compatible with any framing system.

In one embodiment, the throughfeed between the interior of the building and the glazing pocket includes a flex circuit. However, any suitable penetration of the seal can be used, or any method of wireless energy transfer can be used, such as inductive or selective coupling. In other embodiments, the connection may be provided directly to the interior of the building via a sealed hole in the glass, or in other embodiments, the connection may be provided via conductors directly attached to the glass surface. It may be.

Methods for installing and maintaining electrochromic systems according to the present invention are outlined below.

In a first method, an IGU is installed in a glazing pocket while routing a pigtail from the IGU through an access hole in a building pressure plate. The exterior framing cover is then attached by standard means. The hole is then drilled into the cover large enough to reach the interior and make an electrical connection between the glazing and the control module. After the electrical connection between the wireless module and the electrochromic glazing is made, the module is mounted on the frame surface.

In the second method, the IGU is installed in the glazing pocket while routing the pigtail wire from the IGU through the access hole in the building pressure plate. A plug-in connection is then made between the wires passing through the cover and the IGU pigtail wires from a control module pre-mounted on the surface of the frame. The outer framing cover is then attached by standard means.

In a third method, the IGU is installed in the glazing pocket while routing the pigtail wire from the IGU through the access hole in the building pressure plate. In an off-site position, an electronic module and a photovoltaic module are mounted to the framing system cover with photovoltaic cells on the outside and electronics on the inside. On-site, the installer will make the final connection between the cover-mounted electronics and the IGU pigtail. The cover plate is then attached in a conventional manner.

In embodiments aimed at generating photovoltaic power, wires may be added that connect both photovoltaic / electronic modules back to the central collection system to collect excess power. It is then believed that the system will be similar to a regular BIPV (building-integrated photovoltaic system) that is tightly integrated with the electrochromic glazing system. The excess power may, in some embodiments, be converted to grid power with an inverter, or by the Emerging Alliance, for improved efficiency and reduced installation costs through a grid-tie system. Direct connection to a low voltage distribution system, as defined.

In some embodiments, the PV modules and electronics are mounted on glass rather than a framing system without the holes needed to penetrate the wiring. It is believed that the installation of these embodiments is simpler, since it can be installed exactly like other types of glazing. In such cases, the photovoltaic panel and electronic module may reach an already attached installation location, or they may be installed at the rear, which makes the glazing more difficult to process and install but can minimize installation labor.

The present invention can be applied to other types of electroactive glazings, such as including LED light emitting or automated blinds.

Although the invention has been described herein with reference to specific embodiments, it should be understood that these embodiments are merely illustrative of the principles and applications of the invention. It is therefore to be understood that many modifications may be made to the exemplary embodiments and that other configurations may be devised without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (25)

A device for modulating light transmission from a light source, comprising: electrochromic glazing having a light transmission that is variable in response to electrical current; At least one photovoltaic module electrically connected to the electrochromic glazing to provide the current to the electrochromic glazing in response to light from the light source incident on the photovoltaic module; And an electronic module in communication with either the photovoltaic module or the electrochromic glazing. The method of claim 1,
And the electronic module is in wireless communication with the building automation system. The method of claim 1,
And the photovoltaic module is mounted adjacent to the electrochromic glazing on an interior or exterior building framework. The method of claim 1,
And the photovoltaic module is mounted in an insulating glazing unit or mounted on an inner or outer surface of the electrochromic glazing. The method of claim 1,
The electrochromic glazing is a laminate of at least two glass panes, and the photovoltaic module is mounted between the laminate glass panes. The light transmitting modulation device of claim 1, wherein the electronic module is mounted in an insulating glazing unit or mounted on an inner or outer surface of the electrochromic glazing. The method of claim 1,
And the electronic module is mounted adjacent to the electrochromic glazing on an interior or exterior building framework. The method of claim 1,
And the photovoltaic module and the electronic module are mounted at different positions. 9. The method of claim 8,
Wherein the photovoltaic module is located on an outer surface, the electronic module is located inside or protrudes into the framing system, the electronic module in wireless communication with a building automation system. 9. The method of claim 8,
The photovoltaic module is located on an exterior surface, the electronic module is located within an internal framework, and the electronic module is in wireless communication with a building automation system. The method of claim 10,
The electronic module also includes a battery. 9. The method of claim 8,
The photovoltaic module is located on an insulated glazing surface therein, the electronic module is located in an internal framework, the electronic module is in wireless communication with a building automation system, and the electronic module also includes a battery. Modulation device. The method of claim 12,
And the photovoltaic module is located in an electrochromic glass laminate. The method of claim 1,
And the photovoltaic module and the electronic module are combined into a single unit. 15. The method of claim 14,
The combined photovoltaic module and electronic module have a thickness of less than about 10 mm. The method of claim 1,
And the electronic module is responsive to solar intensity such that the electrochromic glazing is tinted or colored in proportion to the available sunlight. The device of claim 1, wherein the electronic module comprises control logic means. 18. The method of claim 17,
And the control logic means to monitor the available energy from the photovoltaic module. The method of claim 1,
And a battery further comprising a battery. The method of claim 1,
And the photovoltaic module and the electronic module are coupled and mounted adjacent to the electrochromic glazing on a building framework. 21. The method of claim 20,
And the electronic module is in wireless communication with the building automation system. The method of claim 1,
The electronic module includes a photovoltaic module and a resistor wired in parallel with the electrochromic glazing wiring. The method of claim 1,
And the photovoltaic module is connected to the electronic module via electrical feed-through. The method of claim 1,
The photovoltaic module is coupled to the electronic module via wireless energy transfer means. A device for modulating the transmission of light from a light source, comprising: an electrochromic glazing having a light transmittance that is changeable in response to a current; At least one photovoltaic module electrically connected to the electrochromic glazing to provide the current to the electrochromic glazing in response to light from a light source incident on the photovoltaic module; And an electronic module in communication with either the photovoltaic module or the electrochromic glazing, the electronic module in wireless communication with a building automation system.

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